In certain aspects, a memory device includes a memory string including a drain select gate (DSG) transistor, a plurality of memory cells, and a source select gate (SSG) transistor, and a peripheral circuit coupled to the memory string. The peripheral circuit is configured to in response to an interrupt during a program operation on a select memory cell of the plurality of memory cells, turn on at least one of the DSG transistor or the SSG transistor. The peripheral circuit is also configured to suspend the program operation after turning on the at least one of the DSG transistor or the SSG transistor.

A method of controlling a memory device includes receiving a write instruction; starting a write operation to a first address in response to the write instruction; receiving a first read instruction of the first address; suspending the write operation; and applying a read voltage to a word line corresponding to the first address in a first read operation in response to the first read instruction.

Embodiments of the disclosed technology relate to a memory system, a memory controller, and an operation method of the memory system. According to embodiments of the present disclosure, the memory system may calculate a time period T1 that is between a beginning of a program operation on a memory page included in the memory device and a suspension of the program operation, may calculate a time period T2 that is between the suspension of the program operation and a time point that is before a resumption of the program operation, may calculate, based on the time period T1 and the time period T2, a read offset voltage to be applied to the memory cell to mitigate the change of the threshold voltage distribution, and may store the read offset voltage in the memory page in the memory device before the resumption of the program operation. Accordingly, the memory system is able to improve the reliability of operations of suspending and resuming a program operation and to improve the performance of a read operation.

A semiconductor memory device according to an embodiment includes a plurality of planes including a plurality of blocks each being a set of memory cells, and a sequencer configured to execute a first operation and a second operation shorter than the first operation. Upon receiving a first command set that instructs execution of the first operation, the sequencer is configured to execute the first operation. Upon receiving a second command set that instructs execution of the second operation while the first operation is being executed, the sequencer is configured to suspend the first operation and execute the second operation or execute the second operation in parallel with the first operation, based on an address of a block that is a target of the first operation and an address of a block that is a target of the second operation.

An operating method of a nonvolatile memory device includes receiving, at the nonvolatile memory device, a suspend command, suspending, at the nonvolatile memory device, a program operation being performed, in response to the suspend command, receiving, at the nonvolatile memory device, a resume command, and resuming, at the nonvolatile memory device, the suspended program operation in response to the resume command. The program operation includes program loops, each of which includes a bit line setup interval, a program interval, and a verify interval. In the program interval of each of the program loops, a level of a program voltage to be applied to selected memory cells of the nonvolatile memory device increases as much as a first voltage. A difference between a level of the program voltage finally applied s suspend and a level of the program voltage applied first after resume is different from the first voltage.

Embodiments of the present disclosure are directed towards techniques and configurations for a memory apparatus configured with an erase command comprising a sequence of segments. In one embodiment, the memory apparatus is configured to generate an erase command in response to a request provided by a host to erase at least a portion of data stored in a memory device. The erase command comprises a sequence of erase segments that provide an erase voltage for erasing the portion of data stored in the memory apparatus. The memory apparatus is configured to grant access to the memory apparatus for servicing the memory access requests initiated by the host, during a time period between at least two adjacent erase segments in the sequence. Other embodiments may be described and/or claimed.

A method of controlling a memory device includes receiving a write instruction; starting a write operation to a first address in response to the write instruction; receiving a first read instruction of the first address; suspending the write operation; and applying a read voltage to a word line corresponding to the first address in a first read operation in response to the first read instruction. The method further includes resuming the write operation is after applying the read voltage; receiving a second read instruction after applying the read voltage; and outputting read data from a data register in response to the second read instruction during a period starting at resuming the write operation and ending at completion of the write operation.

A semiconductor storage device includes a memory cell connected to a word line, and a control circuit configured to execute a write operation that repeats a program loop including a program operation of applying a program voltage to the word line and a verification operation to be executed after the program operation. The control circuit, during the write operation, increases the program voltage by a first amount each time the program loop is repeated, and after the write operation is interrupted and resumed, changes the increase in the program voltage from the first amount to a second amount, which is a positive number smaller than the first amount.

A system includes a memory component and a processing device, operatively coupled with the memory component, to send a read command to the memory component while a program or erase operation being executed by the memory component is suspended. The processing device, operatively coupled with the memory component, can then send an auto resume command to the memory component to automatically resume execution of the program or erase operation after the read command is executed.

A semiconductor storage device includes a first memory die. The first memory die includes a first memory plane including a plurality of first memory blocks, a second memory plane including a plurality of second memory blocks, a first sequencer, and a second sequencer. The first sequencer is configured to start a first write sequence with respect to one of the first memory blocks in response to a first command set designating the one of the first memory blocks if no write sequence is being performed by the first sequencer. The second sequencer is configured to start a second write sequence with respect to one of the second memory blocks in response to a second command set designating the one of the second memory blocks if the first sequencer is performing the first write sequence and no write sequence is being performed by the second sequencer.